src/third_party/llvm-project/clang/test/Sema/builtins.c - cobalt - Git at Google

 // RUN: %clang_cc1 %s -fsyntax-only -verify -pedantic -Wstrlcpy-strlcat-size -Wno-string-plus-int -triple=i686-apple-darwin9
 // This test needs to set the target because it uses __builtin_ia32_vec_ext_v4si

 int test1(float a, int b) {
   return __builtin_isless(a, b); // expected-note {{declared here}}
 }
 int test2(int a, int b) {
   return __builtin_islessequal(a, b);  // expected-error {{floating point type}}
 }

 int test3(double a, float b) {
   return __builtin_isless(a, b);
 }
 int test4(int* a, double b) {
   return __builtin_islessequal(a, b);  // expected-error {{floating point type}}
 }

 int test5(float a, long double b) {
   return __builtin_isless(a, b, b);  // expected-error {{too many arguments}}
 }
 int test6(float a, long double b) {
   return __builtin_islessequal(a);  // expected-error {{too few arguments}}
 }


 #define CFSTR __builtin___CFStringMakeConstantString
 void test7() {
   const void *X;
   X = CFSTR("\242"); // expected-warning {{input conversion stopped}}
   X = CFSTR("\0"); // no-warning
   X = CFSTR(242); // expected-error {{CFString literal is not a string constant}} expected-warning {{incompatible integer to pointer conversion}}
   X = CFSTR("foo", "bar"); // expected-error {{too many arguments to function call}}
 }


 // atomics.

 void test9(short v) {
   unsigned i, old;

   old = __sync_fetch_and_add();  // expected-error {{too few arguments to function call}}
   old = __sync_fetch_and_add(&old);  // expected-error {{too few arguments to function call}}
   old = __sync_fetch_and_add((unsigned*)0, 42i); // expected-warning {{imaginary constants are a GNU extension}}

   // PR7600: Pointers are implicitly casted to integers and back.
   void *old_ptr = __sync_val_compare_and_swap((void**)0, 0, 0);

   // Ensure the return type is correct even when implicit casts are stripped
   // away. This triggers an assertion while checking the comparison otherwise.
   if (__sync_fetch_and_add(&old, 1) == 1) {
   }
 }

 // overloaded atomics should be declared only once.
 void test9_1(volatile int* ptr, int val) {
   __sync_fetch_and_add_4(ptr, val);
 }
 void test9_2(volatile int* ptr, int val) {
   __sync_fetch_and_add(ptr, val);
 }
 void test9_3(volatile int* ptr, int val) {
   __sync_fetch_and_add_4(ptr, val);
   __sync_fetch_and_add(ptr, val);
   __sync_fetch_and_add(ptr, val);
   __sync_fetch_and_add_4(ptr, val);
   __sync_fetch_and_add_4(ptr, val);
 }

 void test9_4(volatile int* ptr, int val) {
   // expected-warning@+1 {{the semantics of this intrinsic changed with GCC version 4.4 - the newer semantics are provided here}}
   __sync_fetch_and_nand(ptr, val);
 }

 // rdar://7236819
 void test10(void) __attribute__((noreturn));

 void test10(void) {
   __asm__("int3");
   __builtin_unreachable();

   // No warning about falling off the end of a noreturn function.
 }

 void test11(int X) {
   switch (X) {
   case __builtin_eh_return_data_regno(0):  // constant foldable.
     break;
   }

   __builtin_eh_return_data_regno(X);  // expected-error {{argument to '__builtin_eh_return_data_regno' must be a constant integer}}
 }

 // PR5062
 void test12(void) __attribute__((__noreturn__));
 void test12(void) {
   __builtin_trap();  // no warning because trap is noreturn.
 }

 void test_unknown_builtin(int a, int b) {
   __builtin_isles(a, b); // expected-error{{use of unknown builtin}} \
                          // expected-note{{did you mean '__builtin_isless'?}}
 }

 int test13() {
   __builtin_eh_return(0, 0); // no warning, eh_return never returns.
 }

 // <rdar://problem/8228293>
 void test14() {
   int old;
   old = __sync_fetch_and_min((volatile int *)&old, 1);
 }

 // <rdar://problem/8336581>
 void test15(const char *s) {
   __builtin_printf("string is %s\n", s);
 }

 // PR7885
 int test16() {
   return __builtin_constant_p() + // expected-error{{too few arguments}}
          __builtin_constant_p(1, 2); // expected-error {{too many arguments}}
 }

 const int test17_n = 0;
 const char test17_c[] = {1, 2, 3, 0};
 const char test17_d[] = {1, 2, 3, 4};
 typedef int __attribute__((vector_size(16))) IntVector;
 struct Aggregate { int n; char c; };
 enum Enum { EnumValue1, EnumValue2 };

 typedef __typeof(sizeof(int)) size_t;
 size_t strlen(const char *);

 void test17() {
 #define ASSERT(...) { int arr[(__VA_ARGS__) ? 1 : -1]; }
 #define T(...) ASSERT(__builtin_constant_p(__VA_ARGS__))
 #define F(...) ASSERT(!__builtin_constant_p(__VA_ARGS__))

   // __builtin_constant_p returns 1 if the argument folds to:
   //  - an arithmetic constant with value which is known at compile time
   T(test17_n);
   T(&test17_c[3] - test17_c);
   T(3i + 5); // expected-warning {{imaginary constant}}
   T(4.2 * 7.6);
   T(EnumValue1);
   T((enum Enum)(int)EnumValue2);

   //  - the address of the first character of a string literal, losslessly cast
   //    to any type
   T("string literal");
   T((double*)"string literal");
   T("string literal" + 0);
   T((long)"string literal");

   // ... and otherwise returns 0.
   F("string literal" + 1);
   F(&test17_n);
   F(test17_c);
   F(&test17_c);
   F(&test17_d);
   F((struct Aggregate){0, 1});
   F((IntVector){0, 1, 2, 3});

   // Ensure that a technique used in glibc is handled correctly.
 #define OPT(...) (__builtin_constant_p(__VA_ARGS__) && strlen(__VA_ARGS__) < 4)
   // FIXME: These are incorrectly treated as ICEs because strlen is treated as
   // a builtin.
   ASSERT(OPT("abc"));
   ASSERT(!OPT("abcd"));
   // In these cases, the strlen is non-constant, but the __builtin_constant_p
   // is 0: the array size is not an ICE but is foldable.
   ASSERT(!OPT(test17_c));        // expected-warning {{folded}}
   ASSERT(!OPT(&test17_c[0]));    // expected-warning {{folded}}
   ASSERT(!OPT((char*)test17_c)); // expected-warning {{folded}}
   ASSERT(!OPT(test17_d));        // expected-warning {{folded}}
   ASSERT(!OPT(&test17_d[0]));    // expected-warning {{folded}}
   ASSERT(!OPT((char*)test17_d)); // expected-warning {{folded}}

 #undef OPT
 #undef T
 #undef F
 }

 void test18() {
   char src[1024];
   char dst[2048];
   size_t result;
   void *ptr;

   ptr = __builtin___memccpy_chk(dst, src, '\037', sizeof(src), sizeof(dst));
   result = __builtin___strlcpy_chk(dst, src, sizeof(dst), sizeof(dst));
   result = __builtin___strlcat_chk(dst, src, sizeof(dst), sizeof(dst));

   ptr = __builtin___memccpy_chk(dst, src, '\037', sizeof(src));      // expected-error {{too few arguments to function call}}
   ptr = __builtin___strlcpy_chk(dst, src, sizeof(dst), sizeof(dst)); // expected-warning {{incompatible integer to pointer conversion}}
   ptr = __builtin___strlcat_chk(dst, src, sizeof(dst), sizeof(dst)); // expected-warning {{incompatible integer to pointer conversion}}
 }

 void no_ms_builtins() {
   __assume(1); // expected-warning {{implicit declaration}}
   __noop(1); // expected-warning {{implicit declaration}}
   __debugbreak(); // expected-warning {{implicit declaration}}
 }

 void unavailable() {
   __builtin_operator_new(0); // expected-error {{'__builtin_operator_new' is only available in C++}}
   __builtin_operator_delete(0); // expected-error {{'__builtin_operator_delete' is only available in C++}}
 }

 // rdar://18259539
 size_t strlcpy(char * restrict dst, const char * restrict src, size_t size);
 size_t strlcat(char * restrict dst, const char * restrict src, size_t size);

 void Test19(void)
 {
         static char b[40];
         static char buf[20];

         strlcpy(buf, b, sizeof(b)); // expected-warning {{size argument in 'strlcpy' call appears to be size of the source; expected the size of the destination}} \\
                                     // expected-note {{change size argument to be the size of the destination}}
         __builtin___strlcpy_chk(buf, b, sizeof(b), __builtin_object_size(buf, 0)); // expected-warning {{size argument in '__builtin___strlcpy_chk' call appears to be size of the source; expected the size of the destination}} \
                                     // expected-note {{change size argument to be the size of the destination}} \
 				    // expected-warning {{'__builtin___strlcpy_chk' will always overflow destination buffer}}

         strlcat(buf, b, sizeof(b)); // expected-warning {{size argument in 'strlcat' call appears to be size of the source; expected the size of the destination}} \
                                     // expected-note {{change size argument to be the size of the destination}}

         __builtin___strlcat_chk(buf, b, sizeof(b), __builtin_object_size(buf, 0)); // expected-warning {{size argument in '__builtin___strlcat_chk' call appears to be size of the source; expected the size of the destination}} \
                                                                                    // expected-note {{change size argument to be the size of the destination}} \
 				                                                   // expected-warning {{'__builtin___strlcat_chk' will always overflow destination buffer}}
 }

 // rdar://11076881
 char * Test20(char *p, const char *in, unsigned n)
 {
     static char buf[10];

     __builtin___memcpy_chk (&buf[6], in, 5, __builtin_object_size (&buf[6], 0)); // expected-warning {{'__builtin___memcpy_chk' will always overflow destination buffer}}

     __builtin___memcpy_chk (p, "abcde", n, __builtin_object_size (p, 0));

     __builtin___memcpy_chk (&buf[5], "abcde", 5, __builtin_object_size (&buf[5], 0));

     __builtin___memcpy_chk (&buf[5], "abcde", n, __builtin_object_size (&buf[5], 0));

     __builtin___memcpy_chk (&buf[6], "abcde", 5, __builtin_object_size (&buf[6], 0)); // expected-warning {{'__builtin___memcpy_chk' will always overflow destination buffer}}

     return buf;
 }

 void test21(const int *ptr) {
   __sync_fetch_and_add(ptr, 1); // expected-error{{address argument to atomic builtin cannot be const-qualified ('const int *' invalid)}}
   __atomic_fetch_add(ptr, 1, 0);  // expected-error {{address argument to atomic operation must be a pointer to non-const type ('const int *' invalid)}}
 }

 void test22(void) {
   (void)__builtin_signbit(); // expected-error{{too few arguments to function call, expected 1, have 0}}
   (void)__builtin_signbit(1.0, 2.0, 3.0); // expected-error{{too many arguments to function call, expected 1, have 3}}
   (void)__builtin_signbit(1); // expected-error {{floating point classification requires argument of floating point type (passed in 'int')}}
   (void)__builtin_signbit(1.0);
   (void)__builtin_signbit(1.0f);
   (void)__builtin_signbit(1.0L);

   (void)__builtin_signbitf(); // expected-error{{too few arguments to function call, expected 1, have 0}}
   (void)__builtin_signbitf(1.0, 2.0, 3.0); // expected-error{{too many arguments to function call, expected 1, have 3}}
   (void)__builtin_signbitf(1);
   (void)__builtin_signbitf(1.0);
   (void)__builtin_signbitf(1.0f);
   (void)__builtin_signbitf(1.0L);

   (void)__builtin_signbitl(); // expected-error{{too few arguments to function call, expected 1, have 0}}
   (void)__builtin_signbitl(1.0, 2.0, 3.0); // expected-error{{too many arguments to function call, expected 1, have 3}}
   (void)__builtin_signbitl(1);
   (void)__builtin_signbitl(1.0);
   (void)__builtin_signbitl(1.0f);
   (void)__builtin_signbitl(1.0L);
 }
	// RUN: %clang_cc1 %s -fsyntax-only -verify -pedantic -Wstrlcpy-strlcat-size -Wno-string-plus-int -triple=i686-apple-darwin9
	// This test needs to set the target because it uses __builtin_ia32_vec_ext_v4si

	int test1(float a, int b) {
	return __builtin_isless(a, b); // expected-note {{declared here}}
	}
	int test2(int a, int b) {
	return __builtin_islessequal(a, b); // expected-error {{floating point type}}
	}

	int test3(double a, float b) {
	return __builtin_isless(a, b);
	}
	int test4(int* a, double b) {
	return __builtin_islessequal(a, b); // expected-error {{floating point type}}
	}

	int test5(float a, long double b) {
	return __builtin_isless(a, b, b); // expected-error {{too many arguments}}
	}
	int test6(float a, long double b) {
	return __builtin_islessequal(a); // expected-error {{too few arguments}}
	}


	#define CFSTR __builtin___CFStringMakeConstantString
	void test7() {
	const void *X;
	X = CFSTR("\242"); // expected-warning {{input conversion stopped}}
	X = CFSTR("\0"); // no-warning
	X = CFSTR(242); // expected-error {{CFString literal is not a string constant}} expected-warning {{incompatible integer to pointer conversion}}
	X = CFSTR("foo", "bar"); // expected-error {{too many arguments to function call}}
	}


	// atomics.

	void test9(short v) {
	unsigned i, old;

	old = __sync_fetch_and_add(); // expected-error {{too few arguments to function call}}
	old = __sync_fetch_and_add(&old); // expected-error {{too few arguments to function call}}
	old = __sync_fetch_and_add((unsigned*)0, 42i); // expected-warning {{imaginary constants are a GNU extension}}

	// PR7600: Pointers are implicitly casted to integers and back.
	void old_ptr = __sync_val_compare_and_swap((void*)0, 0, 0);

	// Ensure the return type is correct even when implicit casts are stripped
	// away. This triggers an assertion while checking the comparison otherwise.
	if (__sync_fetch_and_add(&old, 1) == 1) {
	}
	}

	// overloaded atomics should be declared only once.
	void test9_1(volatile int* ptr, int val) {
	__sync_fetch_and_add_4(ptr, val);
	}
	void test9_2(volatile int* ptr, int val) {
	__sync_fetch_and_add(ptr, val);
	}
	void test9_3(volatile int* ptr, int val) {
	__sync_fetch_and_add_4(ptr, val);
	__sync_fetch_and_add(ptr, val);
	__sync_fetch_and_add(ptr, val);
	__sync_fetch_and_add_4(ptr, val);
	__sync_fetch_and_add_4(ptr, val);
	}

	void test9_4(volatile int* ptr, int val) {
	// expected-warning@+1 {{the semantics of this intrinsic changed with GCC version 4.4 - the newer semantics are provided here}}
	__sync_fetch_and_nand(ptr, val);
	}

	// rdar://7236819
	void test10(void) __attribute__((noreturn));

	void test10(void) {
	__asm__("int3");
	__builtin_unreachable();

	// No warning about falling off the end of a noreturn function.
	}

	void test11(int X) {
	switch (X) {
	case __builtin_eh_return_data_regno(0): // constant foldable.
	break;
	}

	__builtin_eh_return_data_regno(X); // expected-error {{argument to '__builtin_eh_return_data_regno' must be a constant integer}}
	}

	// PR5062
	void test12(void) __attribute__((__noreturn__));
	void test12(void) {
	__builtin_trap(); // no warning because trap is noreturn.
	}

	void test_unknown_builtin(int a, int b) {
	__builtin_isles(a, b); // expected-error{{use of unknown builtin}} \
	// expected-note{{did you mean '__builtin_isless'?}}
	}

	int test13() {
	__builtin_eh_return(0, 0); // no warning, eh_return never returns.
	}

	// <rdar://problem/8228293>
	void test14() {
	int old;
	old = __sync_fetch_and_min((volatile int *)&old, 1);
	}

	// <rdar://problem/8336581>
	void test15(const char *s) {
	__builtin_printf("string is %s\n", s);
	}

	// PR7885
	int test16() {
	return __builtin_constant_p() + // expected-error{{too few arguments}}
	__builtin_constant_p(1, 2); // expected-error {{too many arguments}}
	}

	const int test17_n = 0;
	const char test17_c[] = {1, 2, 3, 0};
	const char test17_d[] = {1, 2, 3, 4};
	typedef int __attribute__((vector_size(16))) IntVector;
	struct Aggregate { int n; char c; };
	enum Enum { EnumValue1, EnumValue2 };

	typedef __typeof(sizeof(int)) size_t;
	size_t strlen(const char *);

	void test17() {
	#define ASSERT(...) { int arr[(__VA_ARGS__) ? 1 : -1]; }
	#define T(...) ASSERT(__builtin_constant_p(__VA_ARGS__))
	#define F(...) ASSERT(!__builtin_constant_p(__VA_ARGS__))

	// __builtin_constant_p returns 1 if the argument folds to:
	// - an arithmetic constant with value which is known at compile time
	T(test17_n);
	T(&test17_c[3] - test17_c);
	T(3i + 5); // expected-warning {{imaginary constant}}
	T(4.2 * 7.6);
	T(EnumValue1);
	T((enum Enum)(int)EnumValue2);

	// - the address of the first character of a string literal, losslessly cast
	// to any type
	T("string literal");
	T((double*)"string literal");
	T("string literal" + 0);
	T((long)"string literal");

	// ... and otherwise returns 0.
	F("string literal" + 1);
	F(&test17_n);
	F(test17_c);
	F(&test17_c);
	F(&test17_d);
	F((struct Aggregate){0, 1});
	F((IntVector){0, 1, 2, 3});

	// Ensure that a technique used in glibc is handled correctly.
	#define OPT(...) (__builtin_constant_p(__VA_ARGS__) && strlen(__VA_ARGS__) < 4)
	// FIXME: These are incorrectly treated as ICEs because strlen is treated as
	// a builtin.
	ASSERT(OPT("abc"));
	ASSERT(!OPT("abcd"));
	// In these cases, the strlen is non-constant, but the __builtin_constant_p
	// is 0: the array size is not an ICE but is foldable.
	ASSERT(!OPT(test17_c)); // expected-warning {{folded}}
	ASSERT(!OPT(&test17_c[0])); // expected-warning {{folded}}
	ASSERT(!OPT((char*)test17_c)); // expected-warning {{folded}}
	ASSERT(!OPT(test17_d)); // expected-warning {{folded}}
	ASSERT(!OPT(&test17_d[0])); // expected-warning {{folded}}
	ASSERT(!OPT((char*)test17_d)); // expected-warning {{folded}}

	#undef OPT
	#undef T
	#undef F
	}

	void test18() {
	char src[1024];
	char dst[2048];
	size_t result;
	void *ptr;

	ptr = __builtin___memccpy_chk(dst, src, '\037', sizeof(src), sizeof(dst));
	result = __builtin___strlcpy_chk(dst, src, sizeof(dst), sizeof(dst));
	result = __builtin___strlcat_chk(dst, src, sizeof(dst), sizeof(dst));

	ptr = __builtin___memccpy_chk(dst, src, '\037', sizeof(src)); // expected-error {{too few arguments to function call}}
	ptr = __builtin___strlcpy_chk(dst, src, sizeof(dst), sizeof(dst)); // expected-warning {{incompatible integer to pointer conversion}}
	ptr = __builtin___strlcat_chk(dst, src, sizeof(dst), sizeof(dst)); // expected-warning {{incompatible integer to pointer conversion}}
	}

	void no_ms_builtins() {
	__assume(1); // expected-warning {{implicit declaration}}
	__noop(1); // expected-warning {{implicit declaration}}
	__debugbreak(); // expected-warning {{implicit declaration}}
	}

	void unavailable() {
	__builtin_operator_new(0); // expected-error {{'__builtin_operator_new' is only available in C++}}
	__builtin_operator_delete(0); // expected-error {{'__builtin_operator_delete' is only available in C++}}
	}

	// rdar://18259539
	size_t strlcpy(char * restrict dst, const char * restrict src, size_t size);
	size_t strlcat(char * restrict dst, const char * restrict src, size_t size);

	void Test19(void)
	{
	static char b[40];
	static char buf[20];

	strlcpy(buf, b, sizeof(b)); // expected-warning {{size argument in 'strlcpy' call appears to be size of the source; expected the size of the destination}} \\
	// expected-note {{change size argument to be the size of the destination}}
	__builtin___strlcpy_chk(buf, b, sizeof(b), __builtin_object_size(buf, 0)); // expected-warning {{size argument in '__builtin___strlcpy_chk' call appears to be size of the source; expected the size of the destination}} \
	// expected-note {{change size argument to be the size of the destination}} \
	// expected-warning {{'__builtin___strlcpy_chk' will always overflow destination buffer}}

	strlcat(buf, b, sizeof(b)); // expected-warning {{size argument in 'strlcat' call appears to be size of the source; expected the size of the destination}} \
	// expected-note {{change size argument to be the size of the destination}}

	__builtin___strlcat_chk(buf, b, sizeof(b), __builtin_object_size(buf, 0)); // expected-warning {{size argument in '__builtin___strlcat_chk' call appears to be size of the source; expected the size of the destination}} \
	// expected-note {{change size argument to be the size of the destination}} \
	// expected-warning {{'__builtin___strlcat_chk' will always overflow destination buffer}}
	}

	// rdar://11076881
	char * Test20(char p, const char in, unsigned n)
	{
	static char buf[10];

	__builtin___memcpy_chk (&buf[6], in, 5, __builtin_object_size (&buf[6], 0)); // expected-warning {{'__builtin___memcpy_chk' will always overflow destination buffer}}

	__builtin___memcpy_chk (p, "abcde", n, __builtin_object_size (p, 0));

	__builtin___memcpy_chk (&buf[5], "abcde", 5, __builtin_object_size (&buf[5], 0));

	__builtin___memcpy_chk (&buf[5], "abcde", n, __builtin_object_size (&buf[5], 0));

	__builtin___memcpy_chk (&buf[6], "abcde", 5, __builtin_object_size (&buf[6], 0)); // expected-warning {{'__builtin___memcpy_chk' will always overflow destination buffer}}

	return buf;
	}

	void test21(const int *ptr) {
	__sync_fetch_and_add(ptr, 1); // expected-error{{address argument to atomic builtin cannot be const-qualified ('const int *' invalid)}}
	__atomic_fetch_add(ptr, 1, 0); // expected-error {{address argument to atomic operation must be a pointer to non-const type ('const int *' invalid)}}
	}

	void test22(void) {
	(void)__builtin_signbit(); // expected-error{{too few arguments to function call, expected 1, have 0}}
	(void)__builtin_signbit(1.0, 2.0, 3.0); // expected-error{{too many arguments to function call, expected 1, have 3}}
	(void)__builtin_signbit(1); // expected-error {{floating point classification requires argument of floating point type (passed in 'int')}}
	(void)__builtin_signbit(1.0);
	(void)__builtin_signbit(1.0f);
	(void)__builtin_signbit(1.0L);

	(void)__builtin_signbitf(); // expected-error{{too few arguments to function call, expected 1, have 0}}
	(void)__builtin_signbitf(1.0, 2.0, 3.0); // expected-error{{too many arguments to function call, expected 1, have 3}}
	(void)__builtin_signbitf(1);
	(void)__builtin_signbitf(1.0);
	(void)__builtin_signbitf(1.0f);
	(void)__builtin_signbitf(1.0L);

	(void)__builtin_signbitl(); // expected-error{{too few arguments to function call, expected 1, have 0}}
	(void)__builtin_signbitl(1.0, 2.0, 3.0); // expected-error{{too many arguments to function call, expected 1, have 3}}
	(void)__builtin_signbitl(1);
	(void)__builtin_signbitl(1.0);
	(void)__builtin_signbitl(1.0f);
	(void)__builtin_signbitl(1.0L);
	}